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High Energy Collisions of Black Holes Numerically Revisited

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arxiv 1506.06153 v2 pith:UQ2YO3GT submitted 2015-06-19 gr-qc astro-ph.HEhep-th

High Energy Collisions of Black Holes Numerically Revisited

classification gr-qc astro-ph.HEhep-th
keywords energyinitialnumericalblackcollisionsdataestimatehead-on
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We use fully nonlinear numerical relativity techniques to study high energy head-on collision of nonspinning, equal-mass black holes to estimate the maximum gravitational radiation emitted by these systems. Our simulations include improvements in the construction of initial data, subsequent full numerical evolutions, and the computation of waveforms at infinity. The new initial data significantly reduces the spurious radiation content, allowing for initial speeds much closer to the speed of light, i.e. $v\sim0.99c$. Using these new techniques, We estimate the maximum radiated energy from head-on collisions to be $E_{\text{max}}/M_{\text{ADM}}=0.13\pm0.01$. This value differs from the second-order perturbative $(0.164)$ and zero-frequency-limit $(0.17)$ analytic computations, but is close to those obtained by thermodynamic arguments $(0.134)$ and by previous numerical estimates $(0.14\pm0.03)$.

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